Bubble Seeding Nanocavities: Multiple Polymer Foam Cell Nucleation by Polydimethylsiloxane-Grafted Designer Silica Nanoparticles

Bubble Seeding Nanocavities: Multiple

Polymer Foam Cell Nucleation by

Polydimethylsiloxane-Grafted Designer Silica

Nanoparticles

Shanqiu Liu, Sida Yin, Joost Duvigneau,

*

and G. Julius Vancso

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Cite This:ACS Nano 2020, 14, 1623−1634 Read Online

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sı Supporting Information

ABSTRACT: We describe a successful strategy to substantially enhance cell nucleation efficiency in polymer foams by using designer nanoparticles as nucleating agents. Bare and poly(dimethylsilane) (PDMS)-grafted raspberry-like silica nanoparticles with diameters ranging from∼80 nm to ∼200 nm were synthesized and utilized as highly efficient cell nucleators in CO2-blown nanocellular polymethyl methacrylate (PMMA) foams. The successful synthesis of core−shell nanoparticles was confirmed by Fourier transform infrared spectros-copy, thermogravimetric analysis, Brunauer−Emmett−Teller meas-urements, and transmission electron microscopy. The cell size and cell density of the obtained PMMA micro- and nanocellular foams were determined by scanning electron microscopy. The results show that increased surface roughness enhances the nucleation efficiency of the designer silica particles. This effect is ascribed to a decreased

nucleation free energy for foam cell nucleation in the nanocavities at the melt−nucleator interface. For PDMS grafted raspberry-like silica nanoparticles with diameters of 155 and 200 nm, multiple cell nucleation events were observed. These hybrid particles had nucleation efficiencies of 3.7 and 6.2, respectively. The surprising increase in nucleation efficiency to above unity is ascribed to the significant increase in CO2absorption and capillary condensation in the corresponding PMMA during saturation. This increase results in the presence of large amounts of the physical blowing agent close to energetically favorable nucleation points. Additionally, it is shown that as a consequence of cell coalescence, the increased number of foam cells is rapidly reduced during thefirst seconds of foaming. Hence, the design of highly efficient nucleating particles, as well as careful selection of foam matrix materials, seems to be of pivotal importance for obtaining polymer cellular materials with cell dimensions at the nanoscale. These findings contribute to the fabrication of polymer foams with high thermal insulation capacity and have relevance in general to the area of cellular materials.

KEYWORDS: nanocellular materials, polymer foam, nanocavity, CO2capillary condensation, core−shell nanoparticles

N

anocellular polymer foams are receiving considerable attention from the scientific and industrial commun-ities.1−6 This interest is ascribed to the unexpected and sometimes exciting foam properties when their cells have diameters on the order of a few tens to hundreds of nanometers. For instance, the thermal conductivity of nanocellular foams is significantly reduced as a result of the Knudsen effect provided that the foam density is sufficiently low.2,7 In addition, compared to that of microcellular foams with similar densities, the mechanical performance of these foams in terms of, for example, the Young’s modulus, impact properties and Shore hardness, is significantly improved.8−10 Thus, nanocellular polymer foams with low thermal

con-ductivity can offer great alternative options when considering new classes of materials, for instance, to realize reductions in fuel consumption and CO2emissions in transportation as well as to manage the thermal energy in buildings.

Nanocellular polymer foam structures can be obtained by various strategies, for example, selective extraction/decom-Received: August 28, 2019

Accepted: January 31, 2020

Published: January 31, 2020

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position,11,12 templating/imprinting,13−15 chemical/physical foaming,8,16−20 etc. Among these methods, CO2-based batch foaming is of particular interest, which is ascribed to good control over the foaming conditions as well as to the low cost and environmental friendliness of CO2as a physical blowing agent.9 In batch foaming, the polymer is first saturated with CO2at a few to several hundreds of bars for a given time (on the order of hours to days). Subsequently, foaming is induced by a quick depressurization step that is typically followed by an increase in temperature. This results in an oversaturation of the dissolved CO2 in the polymer gas mixture leading to cell nucleation followed by rapid cell expansion.21The disadvant-age of batch foaming compared to other methods is that it has a relatively small batch size (i.e., on the scale of liters), which limits the industrial relevance of this process. On the other hand, nanocellular foam extrusion, that is, a continuous process, remains challenging, which is ascribed to the difficult control over key physical foaming parameters, for example, CO2solubility, CO2diffusivity, and foaming temperature.

22−24

In addition to the production challenges, nanocellular foams with high porosities (>85%) and cell densities (>1014 cells cm−3) have been rarely reported.4,25−27This is ascribed to the fact that it is difficult to nucleate such high cell densities in the early stages of foaming. In addition, on the time scale of foaming, cell coalesce is hard to avoid. Frequently used strategies to increase the nucleated cell density rely on increasing the physical blowing agent saturation pressure and/or increasing the pressure release rate.3,25,28

The introduction of nanostructured heterogeneous phases to polymers as heterogeneous nucleation sites prior to foaming has also been considered a promising approach. Examples include the use of phase-separated block copolymer domains29−32and inorganic nanofillers.18,33−38

For instance, Rodri ́guez-Pérez and co-workers29reported on CO2-assisted batch foaming of polymethyl methacrylate (PMMA) and poly(methyl methblock-butyl acrylate-block methyl methacrylate) (MAM) blends. The authors demonstrated that foam cells produced from these PMMA/ MAM blends were nucleated in the nanostructured MAM micellar phase, which is ascribed to the high CO2-philicity of the poly(butyl acrylate) phase compared to the PMMA matrix. McClurg and co-workers31 demonstrated that the incorpo-ration of A-B diblock copolymers containing poly-(dimethylsiloxane) as the core block into polystyrene prior to foaming increases the cell density of microcellular polystyrene foams. The nanostructured poly(dimethylsilane) (PDMS) domains were considered efficient nucleation sites because of their high CO₂-philicity as well as the low surface energy of PDMS.

Compared to block copolymer micelles, silica nanoparticles are of particular interest for use as heterogeneous nucleation agents in polymer foaming because of their low cost and easy preparation and the simplicity of employing various surface decoration strategies.39,40For instance, Zhai and co-workers37 demonstrated that the incorporation of silica nanoparticles into polycarbonate prior to foaming resulted in a higher cell density and more uniform cell size distribution than those in the polycarbonate foams containing no silica nanoparticles as nucleating agents. Yang and co-workers41 reported that the decoration of silica nanoparticles with CO2-philic poly(ionic liquid) significantly enhances cell nucleation in CO2-assisted polystyrene foaming compared to polystyrene foams prepared with bare silica nanoparticles as nucleating agents. Despite

these promising results, we note that the nanoparticles utilized so far for nucleation have suffered from poor nucleation efficiencies; that is, the number of foam cells obtained per number of nanoparticles per cm3_{added to the polymer matrix} prior to foaming was small. The nucleation efficiencies for these inorganic particle-based nanofillers are typically far below 0.01.18,41−43 This means that hundreds of added particles result in the formation of only one foam cell during foaming. In these calculations, it is assumed that homogeneous nucleation and cell coalescence can be neglected.3We have reported the successful utilization of PDMS-grafted silica nanoparticles with a silica core diameter of 80 nm with a nucleation efficiency of approximately 0.5 for the preparation of CO₂-blown batch PMMA foams.33 The good efficiency of these particles is ascribed to (i) the low surface energy of the PDMS shell, which reduces the nucleation energy barrier and (ii) the higher local CO2concentration in the PDMS shell (∼75 wt %)

44

than in the PMMA matrix (∼18 wt %).45 Furthermore, we demonstrated that the contribution of line tension significantly reduces the nucleation efficiency of PDMS-grafted nano-particles with a silica core diameter below 40 nm under the used foaming conditions (i.e., CO₂ saturation pressure of 55 bar and foaming at 40°C).33Thus, the use of smaller particles, for example, particles 10 nm in diameter, is considered unfavorable, although it would in principle allow for the addition of the required high number of potential nucleation sites (>1015 _cm−3_{) at relatively low weight percentages of} particle loading. In fact, increasing the weight percentage of particle loading for particles with sufficiently large diameters (>60 nm) to incorporate the required number of potential nucleation sites renders the resulting particle-filled polymer matrix barely foamable. Thus, we conclude that enhanced particle designs are needed to increase the nucleation efficiency to unity and beyond.

The effect of surface roughness (e.g., nanocavities) on the free energy of heterogeneous foam cell nucleation has not been included in the particle design process until now. Yang and co-workers reported46a thermodynamic model and an analytical solution for the free energy of cell nucleation at the nanometer length scale in nanocavities. They showed that cells nucleated from a concave surface have a lower nucleation free energy than cells nucleated fromflat convex surfaces (e.g., spherical particles).47,48Inspired by these results, we considered surface roughness as an important and ignored design parameter for hybrid nucleating particle designs in enhanced nanocellular foaming. We chose a strategy to prepare silica nanoparticles with a superimposed roughened surface morphology. As the particles resemble a raspberry in appearance, we call them raspberry-like silica nanoparticles.

Since the preparation of raspberry-like silica nanoparticles is fairly easy and well described in the literature,49−53 we considered these surface roughened nanoparticles as ideal candidates to explore the effect of nanocavities on cell nucleation of nanocellular foams. For example, He and co-workers51 reported on a method to produce raspberry-like nanoparticles by a self-templated etching route. This method limits the particle diameter to 60 nm or larger. In fact, for the purpose of this work, this size is acceptable since it allowed us to study the effect of particle surface roughness on foam cell nucleation without considering other effects, such as particle curvature.43,54

Here, we show that raspberry-like silica nanoparticles are efficient foam cell nucleators with nucleation efficiencies that

are comparable to their PDMS grafted nearly spherical counterparts. Upon decorating the raspberry-like silica nano-particles with a few nanometer-thick PDMS shell, multiple foam cell nucleation events were observed from a single designer nanoparticle, and the highest nucleation efficiency obtained was 6.2 for particles with an overall core diameter of ∼200 nm. This nucleation efficiency is nearly 40 times higher than that of a pristine nearly spherical silica nanoparticle with a similar diameter. We qualitatively show that the high nucleation efficiency obtained for PDMS-grafted raspberry-like silica nanoparticles is ascribed to a significantly increased absorption of CO2during saturation. This process results in an increased CO₂ concentration close to the PDMS-decorated, energetically favorable nanocavities at the nucleating surface. The utilization of surface cavities combined with optimized surface chemistry for efficient heterogeneous nucleation at the macromolecular length scale is of interest for the production of nanocellular foams with high cell densities and thus superior thermal insulation power.

RESULTS AND DISCUSSION

Core-Shell Raspberry-like Nanoparticle Synthesis and Characterization. Raspberry-like silica nanoparticles (SiO2-R) were synthesized by the reaction of Stöber silica nanoparticles with NaBH₄, followed by the surface grafting of PDMS to yield rough silica core PDMS-shell hybrid nano-particles (SiO₂-RP). The reaction scheme is depicted inFigure 1a. (Hereinafter we abbreviate “nanoparticle” with NP.)

During the reaction of nearly smooth Stöber SiO2 (SiO₂-S) NPs with NaBH4, the high basicity of the dissolved NaBH4 results in the dissociation of Si−O bonds and subsequently in the formation of soluble mono- and polysilicate species. Eventually the silicate species dissolved in the solution become supersaturated which leads to the formation of small SiO₂ domains on the surface of the remaining silica NPs (Figure 1a, step 1).51,55,56

Scanning electron microscopy (SEM) images of SiO₂-S and SiO₂-R NPs with a diameter of approximately 155 nm are shown inFigure 1b,c, respectively. The diameter of the SiO2-R NPs is defined as the diameter of a circle just large enough to enclose the SiO₂-R NP outer surface. Particles with diameters between 80 and 200 nm were prepared (see Materials and Methodssection). Hereinafter, the numbers preceding“SiO2” refer to the apparent particle diameter. For instance, 155SiO2-S refers to an NP with an average diameter of 155 nm.

FromFigure 1c, it is obvious that small silica domains (with diameters of ∼20−30 nm) are present at the surface of the NPs after treatment with NaBH4, which is in agreement with the deposition of silicate species on the silica particle surface during the reaction.51 Following the successful synthesis of SiO2-R NPs with diameters of∼80 nm, ∼120 nm, ∼155 nm, and∼200 nm, a PDMS shell was grafted to the surface to yield the corresponding hybrid (SiO2-RP) NPs (Figure 1a). In brief, SiO₂-R was derivatized with (3-aminopropyl)-triethoxysilane (APTES), resulting in the formation of amine-functionalized NPs (SiO2-R-NH2) (step 2). Subsequently, PDMS-grafted Figure 1. (a) A schematic of the SiO2-RP NP preparation process. In (b) and (c) SEM images of SiO2-S and SiO2-R NPs with a silica particle

diameter of∼155 nm are shown, respectively. (d) Single reflection ATR-FTIR absorbance spectra of 155SiO2-S, 155SiO2-R, 155SiO2

-R-NH2, 155SiO2-RP, and 155SiO2-SP NPs. The black arrows in the FTIR spectra indicate characteristic FTIR absorbance values of the

(modified) silica NPs. (e) Non-isothermal TGA thermograms of the 155SiO2-S-NH2, 155SiO2-R-NH2, 155SiO2-SP, and 155SiO2-RP NPs.

core−shell NPs were prepared by the “grafting to” approach with monoglycidyl ether-terminated PDMS (step 3). We note here that prolonged sonication or even melt blending did not destroy the surface roughness of the (hybrid) raspberry-like NPs; that is, the NPs are stable enough for utilization as nucleating particles in nanocellular foaming.

Figure 1d shows Fourier transform infrared (FTIR) absorbance spectra of SiO2, SiO2-R, SiO2-R-NH2, SiO2-RP, and nearly smooth PDMS-grafted NPs (SiO2-SP) with a (silica core) diameter of ∼155 nm. The ethoxy groups remaining after the Stöber reaction with tetraethyl orthosilicate (TEOS) are clearly observed in the FTIR spectra of the 155SiO₂-S particles; that is, the CH₂/CH₃bending absorbance band at 1452 cm−1 and the CH2/CH3 absorbance band at 2980 cm−1.57After NaBH4etching to yield surface-roughened NPs, these absorbance bands disappear, which indicates quantitative hydrolysis of the remaining ethoxy groups of the 155SiO2-R NPs.51The bands at 2980 cm−1, 1450 cm−1, and 1380 cm−1 reappearing in the FTIR spectrum of 155SiO2-R-NH2 are assigned to the CH2 groups of the propyl spacer of surface tethered APTES. The presence of absorption bands ascribed to CH₃ stretching at 2967 cm−1 and to C−H bending at 1263 cm−1in the FTIR spectrum of 155SiO₂-RP NPs confirms the successful grafting of PDMS.58The same absorption bands are observed in the FTIR spectrum of SiO2-SP NPs; their synthesis is described in theMaterials and Methodssection.

To determine the amount of PDMS grafted to the silica NPs, thermogravimetric analysis (TGA) was employed.Figure 1e shows the weight loss versus temperature curves for non-isothermal TGA measurements of nearly spherical and raspberry-like, amino-functionalized and PDMS-grafted NPs with silica (core) diameters of approximately 155 nm. The results clearly show that the amount of PDMS covalently bound to the SiO2 NPs with a rough surface is significantly higher, that is,∼10.3 wt %, than the amount covalently bound to the spherical NPs, that is, ∼3.0 wt %. This nearly 3.4-fold increase in grafted PDMS weight is ascribed to the increased

specific surface area of the raspberry-like NPs compared to the spherical NPs, as shown in Figure S1. For the NPs with a diameter of 155 nm, the surface area increased from 32.4 m2 g−1for the spherical NPs to 116.0 m2_g−1_{for the raspberry-like} NPs (see Figure S1). The nearly 3.6-fold increase in surface area is in good agreement with the 3.4-fold increase in amount of grafted PDMS. For the raspberry-like silica NPs with diameters of 200 and 120 nm, the increase in PDMS grafting wt % was in good agreement with the corresponding increase in surface area.

Based on the grafted PDMS mass obtained by TGA measurements, the molar mass of the grafted PDMS chains (i.e., 1000 g mol−1), and the Brunauer−Emmett−Teller (BET) surface area of the NPs, the PDMS grafting densities were calculated to be ∼0.6 chains nm−2 for the 155SiO2-SP and 155-SiO2-RP NPs. This number is lower than the earlier reported value of 0.9 for SiO2-SP NPs with diameters from 12 to 120 nm.59 This difference is ascribed to the known overestimation of the surface area of Stöber silica NPs determined by BET measurements60−62compared to the NP surface area calculated by simple arithmetic estimation based on the particle diameter. When using this simple arithmetic method for the determination of the grafting density of the SiO₂-SP NPs with a particle diameter from 80 to 200 nm, grafting density values close to 0.9 chains nm−2were obtained. This result is in good agreement with values for SiO2-SP NPs reported in our previous work.59 Based on these results, we note that BET analysis is used here only to qualitatively show the significant differences in the surface area of the particles before and after roughening their surface.

Finally, transmission electron microscopy (TEM) was used to confirm the core−shell structure of the PDMS-grafted NPs.

Figure 2a−d shows TEM images of 155 nm bare and PDMS-grafted spherical and raspberry-like NPs. From these TEM images, it is clear that there is a thin PDMS shell around the 155SiO2-SP (Figure 2b) and 155SiO2-RP (Figure 2d) NPs. The thickness of the PDMS shell on the NPs was estimated to Figure 2. TEM images of (a) 155SiO2-S, (b) 155SiO2-SP, (c) 155SiO2-R, and (d) 155SiO2-RP NPs.

be approximately 6.0 ± 1.5 nm, which agrees well with previous results reported for SiO₂-SP NPs with silica-core diameters from 12 to 120 nm.59

Following the successful synthesis and characterization of the NPs, we employed them as nucleating agents in CO2 -assisted batch foaming of PMMA as presented and discussed in the next sections.

Nanocomposite Foaming and Multinucleation. Prior to foaming, the designer NPs were melt-blended in a PMMA matrix and pressed intofilms with a thickness of approximately 200μm. For comparison of the nucleation efficiency, NPs with the same volume number density (i.e., 1.07 × 1013_particles cm−3) were used for each nanocompositefilm. Thus, assuming

that the particles are well dispersed in the PMMA films and that each particle can nucleate the same number of foam cells, all nanocompositefilms had the same volume number density of potential nucleation sites prior to foaming. The particles were well dispersed in PMMA prior to foaming, as observed from SEM images of cross-sectioned PMMA nanocomposite films (seeFigure S3, Supporting Information).

The CO2saturation pressure used for foaming was 55 bar, and following quick depressurization (i.e., within 2 s), foams were prepared at a foaming temperature of 40°C for 1 s. This relatively short foaming time was chosen since we were primarily interested in the nucleation efficiency of the prepared particles and not in the well-developed foam morphology at Figure 3. SEM images of cross-sectioned PMMA foams nucleated by (a) 155SiO2-S, (b) 155SiO2SP, (c) 155SiO2-R, (d) 155SiO2-RP, (e)

80SiO2-RP, and (f) 200SiO2-RP NPs. The white arrows in (d) and (f) point toward the particles showing multiple cell nucleation events per

particle. The insets show higher magnification images of nucleating NPs in cross-sectioned PMMA foam cells. The saturation pressure, foaming temperature, and foaming time were 55 bar, 40°C, and 1 s, respectively.

the end stages of foaming (i.e., after several tens of seconds to min). Figure 3a−d shows SEM images of cross-sectioned PMMA foams nucleated by 155SiO₂-S, 155SiO₂-SP, 155SiO₂ -R, and 155SiO₂-RP NPs. It is clear that for the 1 s foaming time, the PMMA foams have thick cell walls and struts. Furthermore, the 155SiO2-S, 155SiO2-SP, and 155SiO2-R NPs are present at the polymer foam cell wall surface. The 155SiO2 -S NPs are more embedded in the PMMA cell wall than the 155SiO2-SP NPs, which can be attributed to the low surface energy and high CO2-philicity of the decorated PDMS shell compared with the bare particles, resulting in the different interfacial interactions between the nanoparticles and the polymer gas mixture.63 This is in good agreement with the reported results for the nucleation behavior of pristine SiO₂ and corresponding PDMS-grafted core−shell NPs with (core) diameters up to 120 nm.33,59

Interestingly, when examining the 155SiO2-RP NPs embedded in the PMMA foams, we observed that most of these particles are surrounded by a few primary polymer foam cells (seeFigure 3d). Of particular interest is that the cell walls in between these primary foam cells are much thinner than the non-nucleated/expanded PMMA matrix surrounding them and that the size of the cells around the 155SiO₂-RP particles is fairly uniform. This observation points toward simultaneous multiple heterogeneous nucleation events per added particle. In addition, the thin wall between some foam cells appears to be ruptured or partly disappeared. This result indicates that cell coalescence occurs during the initial stages of nucleation. An explanation for this behavior is provided later.

The occurrence of multiple nucleation events per 155SiO2 -RP particles is promising for developing nanocellular foams with increased cell densities. To successfully exploit this possibility, it is of pivotal importance to obtain a deeper understanding of cell nucleation as a function of the surface roughening feature sizes. Therefore, we prepared SiO2-R and SiO₂-RP NPs with diameters of∼80 nm, ∼120 nm, and ∼200 nm to explore this idea. Figure S2 shows SEM images of 80SiO₂-R, 120SiO₂-R, and 200SiO₂-R NPs. It is clear that the feature sizes of the roughened surfaces are different among the particles with different diameters, that is, 80SiO2-R has only a few small protrusions at its surface, while 200SiO2-R reveals numerous larger protruding features (Figure S2). It turned out that for the etching method used the initial Stöber silica NP size has an impact on the particle roughness.51

The SEM images of the cross-sectioned PMMA foams nucleated by 80SiO₂-RP (Figure 3e) and 200SiO₂-RP (Figure 3f) reveal distinct differences in the foam morphology as well. For instance, the images of the foam nucleated by 200SiO₂-RP NPs clearly show the presence of multiple cells around single nucleating particles; however, no multiple cell nucleation events are observed around single 80SiO2-RP NPs.

Below, we present how the nucleation efficiency of SiO2-RP NPs depends on the particle surface roughness for a PMMA foam prepared with a foaming time of 1 s.Figure 4shows the cell size (4a), cell density (4b), and nucleation efficiency (4c) values for foams nucleated by SiO₂-S, SiO₂-SP, SiO₂-R, and SiO2-RP NPs as a function of the silica particle diameter.

As can be clearly seen from Figure 4a, the average cell size nucleated with SiO2-RP NPs is smaller than that nucleated Figure 4. (a) Foam cell size, (b) cell density, and (c) cell nucleation efficiency for PMMA foams nucleated by SiO2-S, SiO2-SP, SiO2-R, and

SiO2-RP NPs with diameters of∼80 nm, ∼120 nm, ∼155 nm, and ∼200 nm. The saturation pressure, foaming temperature, and foaming

time were 55 bar, 40°C, and 1 s, respectively. The insets in (c) show SEM images of cross-sectioned PMMA foam cells showing the presence of multiple cells around single 155SiO2-RP and 200SiO2-RP NPs.

with SiO2-S, SiO2-SP and SiO2-R NPs with the same diameter. In addition, upon increasing the particle diameter from 80 to 200 nm, the average cell size decreases, and the cell size distribution becomes narrower. SEM images of cross-sectioned PMMA foams nucleated by 80SiO2-RP particles did not reveal any multiple cell nucleation events per particle (seeFigure 3e), while for 120SiO2-RP, this phenomenon was observed for some particles (Figure S4). The decrease in the number of multiple nucleation events is ascribed to the lower surface roughness of the 80-SiO2-RP and 120SiO2-RP NPs, that is, resulting in a reduced number of effective nanocavities. However, for the PMMA foams nucleated by 155SiO2-RP and 200SiO₂-RP particles, multiple cell nucleation events were observed, resulting in a higher CO₂ consumption during cell growth than that during the growth of the foams without multiple cell nucleation events. This finding explains the reduction in cell size to 160± 50 nm and 110 ± 60 nm for the foams nucleated with 155SiO₂-RP and 200SiO₂-RP particles, respectively.

The occurrence of multiple cell nucleation events for SiO2 -RP NPs with various roughnesses has, as expected, a significant effect on the cell density and nucleation efficiency values (Figure 4b,c). Compared to the other particle types, the 200SiO2-RP NPs cause, similar to the 155SiO2-RP NPs, a significant increase in cell density and cell nucleation efficiency.

In fact, for the 200SiO2-RP NPs, the nucleation efficiency was ∼6.2, which is the highest nucleation efficiency reported thus far.

In addition, 120SiO₂-RP particles have a higher nucleation efficiency than 120SiO2-S, 120SiO2-R, and 120SiO2-SP NPs, as well (seeFigure 4c). This result is again qualitatively explained by the presence of the nanocavities. However, 80SiO2-RP NPs show a comparable nucleation efficiency with 80SiO2-SP NPs, which is ascribed to the presence of mainly convex surface domains at its particle surface. Compared to concave surface roughness, convex structures have a higher cell nucleation free energy.47,48

From Figure 4, it is obvious that for the particle sizes evaluated, the SiO2-R NPs have nucleation efficiencies comparable to those of the SiO2-SP NPs, while the SiO2-S particles are the least effective nucleating agents. Overall, it is shown that NPs designed with a concave surface roughness are more efficient for use as nucleation agents than the nearly spherical NPs and that a combination of roughness with a CO2-philic low surface energy PDMS shell has a very large synergetic effect on PMMA foam cell nucleation.

Elucidation of the Multiple Foam Cell Nucleation Mechanism. The synergetic effect of a PDMS shell with the presence of cavities on the nucleation efficiency of SiO2-RP NPs was much higher than expected. In fact, we reasoned that Figure 5. (a) CO2absorption by PMMAfilms containing SiO2-S, SiO2-SP, SiO2-R, and SiO2-RP particles with diameters between 80 and 200

nm. The saturation pressure and time were 55 bar and 4 h, respectively. The dashed line shows the CO2absorption by PMMA containing no

NPs. (b) Schematic representation of the nucleation of multiple cells from PDMS-grafted raspberry-like silica NPs. SEM images of cross-sectioned PMMA foams nucleated by 155SiO2-RP NPs for (c) 10 s, (d) 5 s, (e) 1 s, and (f) 0.3 s. In the insets, the foam cell wall around a

single nanoparticle is shown. The saturation pressure and foaming temperature were 55 bar and 40°C, respectively.

for the higher number of cells to grow, more CO₂as a blowing agent must be available. Thus, the CO2absorption of PMMA films containing SiO2-S, SiO2-SP, SiO2-R, and SiO2-RP particles with diameters of ∼80 nm, ∼120 nm, ∼155 nm, and ∼200 nm were determined to further elucidate the cell nucleation efficiency as a function of the particle type and size. The results are shown in Figure 5a. Clearly, PMMA films containing SiO₂-S and SiO₂-SP NPs have no significant differences in CO2 absorption from PMMA films without NPs regardless of the particle diameter. The same trend is observed for 80SiO2-R and 80SiO2-RP NPs. Hence, for these particles, the overall CO2 concentration is not altered, while locally in the PMMA films, the CO2 concentration may vary due to the presence of the PDMS shell. Upon increasing the surface roughness of the particles, for example, for the 120SiO2-R, 155SiO2-R, and 200SiO2-R NPs, the amount of CO2 absorbed is expected to significantly increase. The presence of a PDMS shell increases the amount absorbed even more for these NPs. For instance, for the 200SiO2-R and 200SiO₂-RP NPs, the increase in the amount of CO₂absorbed was∼4.7 wt % and ∼8.8 wt %, respectively, compared to the PMMAfilm containing no particles (∼18.2 wt %).

This increase in CO2absorption for the rough particles is ascribed to capillary condensation of CO2 in the nano-cavities.64−66The even larger increase in CO₂absorption for the rough particles with a PDMS shell with diameters of∼120 nm, ∼155 nm, and ∼200 nm compared to their bare counterparts is attributed to the presence of CO2-philic molecules attached to the nanocavity surfaces, which is known to potentially enhance the absorption of CO2.67−69

The higher physical blowing agent concentration close to the particle surface is favorable for increasing the nucleation rate, and combined with the presence of a low surface energy PDMS shell in the nanocavities, this property leads to a significant enhancement in the foam cell nucleation efficiency of these particles.Figure 5b shows a schematic representation of the assumed mechanism leading to multiple cell nucleation events for raspberry-like PDMS-grafted silica NPs. Upon saturation of PMMA films containing SiO2-RP NPs, CO2 capillary condensation in the cavities results in the presence of significantly increased amounts of CO2in close proximity to the nucleating particle surface. The nanocavities are energeti-cally favorable nucleating sites and, together with the increased amount of available CO2, result in more than one nucleating event per particle (step A) and subsequent cell growth (step B) and cell coalescence (step C). This mechanism is further experimentally confirmed by the development of the foam cell morphology as a function of the foaming time for PMMA foams nucleated by 155SiO2-RP NPs, as shown inFigure 5c−f. Upon increasing the foaming time, the cell walls between these primary foam cells nucleated from the same single 155SiO2-RP appear to be ruptured or partly disappeared, leading to cell coalescence. In addition, the cell size and cell nucleation efficiency for PMMA foams, nucleated with 155SiO2-S, 155SiO₂-SP, 155SiO₂-R, and 155SiO₂-RP NPs, were also determined as a function of the foaming time (seeFigure S5). Overall, we experimentally demonstrated that multiple cell nucleation events on a single NP can be obtained through the use of PDMS-decorated core−shell raspberry-like NPs as nucleation agents. These designer NPs exhibit significantly higher cell nucleation efficiency in PMMA nanocellular foaming than their bare and nearly spherical counterparts. We also utilized 155SiO2-RP NPs in the CO2-assisted batch

foaming of polystyrene, and the corresponding SEM images also revealed the occurrence of multiple cell nucleation events (seeFigure S6). Hence, these hybrid core−shell NPs are very promising as highly efficient cell nucleation agents in polymer nanocellular foaming in general.

To fully exploit the high nucleation efficiency of SiO2-RP particles, it is of pivotal importance tofind foaming strategies and foam matrixes that both allow the introduction of a high number of cell nuclei and ensure early cell stabilization during the foaming process to prevent cell coalescence. For instance, without optimization of any of the foaming parameters or the composition of the PMMA nanocomposite matrix, we obtained a high cell density of∼6.6 × 1013cells cm−3, which is already very close to the order of magnitude of interest (i.e., 1014 _{cells cm}−3_{). Future work must be directed toward} developing new strategies for sufficiently increasing the surface roughness of NPs with a particle diameter <100 nm. This objective is essential since at the same weight percentage of particle loading, a higher number of effective nucleation agents is available when smaller particles are used.

CONCLUSION

In summary, bare and PDMS-decorated nearly spherical and raspberry-like silica NPs were synthesized and utilized as efficient nucleation agents in CO2-blown PMMA nanocellular foams. Raspberry-like nanoparticles with a thin PDMS shell exhibit a higher nucleation efficiency than their nearly spherical counterparts. Multiple nucleating events per particle were observed for SiO2-RP NPs with core diameters of 155 and 200 nm. The highest nucleation efficiency obtained was 6.2 for 200SiO2-RP NPs. The significantly higher nucleation efficiency (well above unity) of the core−shell raspberry-like nano-particles is attributed to the synergistic effect between the thin PDMS shell and the presence of cavities on the nanoparticles surface as well as the higher CO₂absorption. This results in an increased physical blowing agent concentration available for nucleation close to the energetically favorable nanocavities serving as nucleating sites. Hence, PDMS-decorated core−shell raspberry-like nanoparticles are very promising for use as an interesting class of highly efficient nucleation agents. To improve our understanding of multiple cell nucleation events, future work should be directed toward the quantification of the relationship between nucleation energy barrier and surface cavity structure dimensions as well optimization of foaming conditions to stabilize the multiple nucleated cells during the early stages of foaming.

MATERIALS AND METHODS

Materials. PMMA was purchased from Arkema (VM100, i.e., a PMMA-co-EA polymer, ρ = 1.18 g cm−3) (La Garenne-Colombes, France). Absolute ethanol for analysis was purchased from Merck (Darmstad, Germany). Absolute tetrahydrofuran (THF), 2-propanol (99.8%), and chloroform (99.9%) were purchased from Biosolve (Valkenswaard, The Netherlands). Monoglycidyl ether-terminated poly(dimethylsilane) (PDMS-G) (Mw= 1000 g mol−1), ammonium

hydroxide solution (28−30%), (3-aminopropyl)triethoxysilane (APTES,≥98%), sodium borohydride purum (NaBH4, p.a.,≥96%,

gas-volumetric), polyvinylpyrrolidone with a molar mass of 40,000 g mol−1(PVP40), and tetraethyl orthosilicate (TEOS, ≥99.0%) were purchased from Sigma-Aldrich (St. Louis, MO, USA). Milli-Q water was produced by a Millipore Synergy system (Billerica, MA, USA). Unless otherwise mentioned, all other chemicals were used as received.

Stöber Silica Nanoparticle (SiO2) Synthesis. SiO2 particles

with diameters of∼80 nm, ∼120 nm, ∼155 nm, ∼180 nm, ∼200 nm, and∼310 nm were prepared by the Stöber method. To prepare NPs with a diameter of∼155 nm, 100 mL of ethanol was mixed with 8 mL of Milli-Q water and 10 mL of TEOS in the presence of 5 mL of ammonium hydroxide while stirring at 500 rpm at 50°C. After 4.5 h, the SiO2 dispersion obtained was centrifuged at 10,000 rpm for 30

min. Subsequently, the collected SiO2was redispersed in ethanol and

centrifuged again. This washing step was repeated 2 more times, followed by vacuum-drying the collected SiO2nanoparticles at room

temperature for 12 h. To prepare NPs with a diameter of∼80 nm, 168 mL of ethanol was mixed with 28 mL of Milli-Q water and 30 mL of TEOS in the presence of 2 mL of ammonium hydroxide while stirring for 1.5 h at 500 rpm at room temperature. To synthesize the ∼120 nm particles, 100 mL of ethanol was mixed with 8 mL of Milli-Q water and 5 mL of TEOS in a round-bottomflask stirring at 500 rpm, and subsequently 5 mL of ammonium hydroxide was added and reacted for 3 h at 50°C. To synthesize the ∼180 nm particles, 100 mL of ethanol was mixed with 8 mL of Milli-Q water and 10 mL of TEOS in the presence of 5.3 mL of ammonium hydroxide in a 250 mL round-bottomflask while stirring at 500 rpm. The reaction was conducted for 4.5 h at 50°C. To synthesize the ∼200 nm particles, 100 mL of ethanol was mixed with 8 mL of Milli-Q water and 10 mL of TEOS in the presence of 5.6 mL of ammonium hydroxide in a 250 mL round-bottomflask while stirring at 500 rpm. The reaction was conducted for 4.5 h at 50°C. To synthesize the ∼310 nm particles, 100 mL of ethanol was mixed with 8 mL of Milli-Q water and 10 mL of TEOS in a round-bottom flask stirring at 500 rpm, and subsequently, 7.0 mL of ammonium hydroxide was added and reacted for 4.5 h at 50°C. The collection, washing, and drying steps of these nanoparticles were the same as those described for the∼155 nm nanoparticles.

Nanoparticles Hydrolysis. To introduce silanol groups on the surface of the prepared SiO2 nanoparticles, the particles were

redispersed in Milli-Q water by sonication (BRANSON 2510, Canada) for 1 h. Subsequently, hydrochloric acid was added to the dispersion while stirring at 500 rpm until the pH of the solution reached a value of approximately 1. After 4 h, the dispersion was centrifuged at 10,000 rpm for 30 min. The collected nanoparticles were redispersed in Milli-Q water and centrifuged again. This washing step was repeated 2 more times, followed by drying the silanol-functionalized nanoparticles (SiO2-OH) under vacuum at room

temperature for 12 h.

APTES Modification of Silica Nanoparticles. First, 1.5 g of SiO2-OH nanoparticles were redispersed in 50 mL of ethanol,

followed by the addition of 7.5 mL of APTES. The dispersion was left stirring at 500 rpm at room temperature for 17 h. The APTES-functionalized nanoparticles (SiO2-NH2) were collected by

centrifu-gation at 10,000 rpm for 30 min, redispersed in ethanol, and centrifuged again. This washing step was repeated 2 more times, followed by drying the collected SiO2-NH2 nanoparticles under

vacuum at room temperature for 12 h.

PDMS-G Grafting to Silica Nanoparticles. First, 1.0 g of SiO2

-NH2NPs was redispersed in 20.5 mL of THF and 15 g of PDMS-G

while stirring at 500 rpm for 1 h, followed by sonication for 1 h. Subsequently, THF was removed by rotary evaporation, and the resulting silica nanoparticle dispersion in PDMS-G was immersed in an oil bath thermostated at 80°C for 17 h. After cooling to room temperature, the reaction mixture was washed with THF and centrifuged at 10,000 rpm for 30 min. This washing step was repeated 2 more times, followed by vacuum-drying the PDMS-G-grafted silica nanoparticles (SiO2-SP) at room temperature for 12 h.

Synthesis and Modification of Raspberry-like Nanopar-ticles. To synthesize NPs with enhanced surface roughness of∼80 nm, 0.3 g of Stöber silica NPs of ∼80 nm and 0.25 g of PVP were redispersed in 10 mL of Milli-Q water by sonication for 30 min. Subsequently, 0.6 g of NaBH4 was added to the dispersion while

stirring at 500 rpm at room temperature for another 30 min. The resulting mixture was reacted at 50°C for 1 h and 15 min. Stöber silica nanoparticles with diameters of∼155 nm, ∼180 nm, and ∼310

nm were used to synthesize surface-roughened nanoparticles of∼120 nm,∼155 nm, and ∼200 nm, respectively, and the reactions were conducted for 3 h and 20 min, 3.5 h, and 6 h, respectively. The other steps for the synthesis of these surface-roughened NPs (with diameters from 120 to 200 nm) were the same as described for the synthesis of rough surface NPs of ∼80 nm. Subsequently, the obtained NPs featuring rough surfaces were collected by centrifuga-tion at 10,000 rpm for 30 min, redispersed in Milli-Q water, and centrifuged again. This washing step was repeated 2 more times, followed by drying the collected nanoparticles under vacuum at room temperature for 12 h. The processes of amino functionalization of and PDMS-G grafting to the surface-roughened nanoparticles were the same as those described for the Stöber silica nanoparticles.

Nanocomposite Preparation. Nanocomposites were prepared by dispersing the same amount of (functionalized) silica nanoparticles (1.07 × 1013cm−3) in PMMA with a mini-extruder (DSM Xplore, The Netherlands). In a typical procedure, a dry blend of nanoparticles and PMMA was fed to the extruder followed by internal mixing for 3 min. The barrel temperature was set to 155°C, and the screw speed was 100 rpm. Subsequently, the PMMA nanocomposite was collected and left to cool to room temperature.

Film Preparation. A hot press (Fontijne, The Netherlands) was used to press∼0.2 mm-thick nanocomposite films in a mold (4 × 3 cm). The press temperature, applied load, and press time were 180 °C, 250 kN, and 10 min, respectively.

Batch Foaming of Nanocomposite Films. The nanocomposite PMMAfilms were saturated with CO2(55 bar) in an autoclave for 4 h

at room temperature followed by rapid depressurization. Subse-quently, the PMMA nanocompositefilms were immersed in a water bath thermostated at 40°C for different foaming times (0.3 s, 1 s, 5 s, 10 s, or 30 s), after which the samples were quenched in an ice bath for 30 min. The samples were left to dry in air for at least 12 h prior to further analysis.

Fourier Transform Infrared Spectroscopy. FTIR spectra were collected with a Bruker ALPHA single attenuated total reflection (ATR) FTIR spectrometer equipped with a single reflection ATR crystal (Bruker Optic GmbH, Ettlingen, Germany). The spectra were collected in the range of 400−4000 cm−1_{(spectral resolution of 4}

cm−1, 128 scans). Background spectra were recorded against air. Thermogravimetric Analysis. The weight loss of the (modified) particles as a function of temperature was measured with a TGA400 (PerkinElmer, Inc., Waltham, MA, USA). A sample weighing∼3−6 mg was loaded into a platinum pan, and the temperature was set to 50 °C to stabilize. Subsequently, the sample was heated to 900 °C at a heating rate of 20°C min−1. The applied airflow was 20 mL min−1. Transmission Electron Microscopy. TEM was performed with an FEI/Philips CM300 system (Eindhoven, The Netherlands). Diluted particle dispersions in THF were deposited on the carbon side of a carbon/copper grid (HC200-Cu) (EMS, Germany) prior to imaging. Images were obtained in the bright-field mode with a 300 kV acceleration voltage.

Scanning Electron Microscopy. For SEM, a high-resolution scanning electron microscope (JEOL Field Emission JSM-633OF, JEOL Benelux, Nieuw-Vennep, The Netherlands) was employed at an acceleration voltage of 5 keV. Prior to analysis, the nanocomposite foams were freeze fractured following cooling in liquid nitrogen for 5 min.

Surface Area Measurement for Nanoparticles. The specific surface area of the nanoparticles was measured from the nitrogen adsorption isotherm obtained at 300 °C using an ASAP 2010 sorptometer (Micromeritics). Approximately 100 mg of nanoparticle powder was used for each measurement.

CO2Absorption Measurement. To measure the absorption of

CO2, PMMA nanocompositefilms containing the same amount of the

respective nanoparticles were saturated in CO2at 55 bar for 4 h. The

weights of the PMMA (nanocomposite)films before and after CO2

saturation were measured.

Calculation of PDMS Grafting Density. The grafting density (D) of the PDMS-decorated NP surface was determined according to eq 1:

= ×

D K m M

S ( / )

(1) whereK = 6.02× 1023_mol−1_{, which is Avogadro’s number, and m is}

the weight of PDMS grafted per gram of NPs (determined from TGA), M = 1000 g·mol−1_{, which is the molar mass of the PDMS used,}

and S is the surface area per gram of NPs, which was determined by BET.

Calculation of Cell Density and Nucleation Efficiency. The cell size and cell density were obtained by analyzing the obtained cross-sectional SEM images. The cell density Nv of the foams was

calculated according to Kumar’s theoretical approximation.70 No direct measurements of cell dimensions over the micrograph are required in this method; only the micrograph area (A) and the total number of cells (n) contained therein are measured. Together with the magnification factor of the micrograph (M), the values enabling Nvto be calculated according toeq 2: = N nM A ( ) v 2 3/2 Ä Ç ÅÅÅÅÅ ÅÅÅÅÅ É Ö ÑÑÑÑÑ ÑÑÑÑÑ (2)

By combining Nv with the volume expansion ratio (B) of

nanocomposite films after foaming, the cell numbers per cm3 _of

unfoamed materials (N) can be calculated according toeq 3:

= ×

N Nv B (3)

The cell densities mentioned in the main text are all refer to N. In addition, the nucleation efficiency (f) of nanoparticles during foaming can be calculated as

=

f N C/ (4)

where C is the number of nanoparticles per cm3_{(i.e., 1.07× 10}13₎

used for foaming.

Figure S7 shows how we calculated the number of cells in the occasion of multiple cell nucleating events occurring around a particle.

ASSOCIATED CONTENT

*

sı Supporting Information

The Supporting Information is available free of charge at

https://pubs.acs.org/doi/10.1021/acsnano.9b06837.

BET results, SEM images for SiO₂-R nanoparticles with different diameters, nanoparticles dispersion in PMMA, and cross-sectioned PMMA foams nucleated by 120SiO2-RP. Cell size and nucleation efficiency as a function of foaming time, and SEM images of cross-sectioned polystyrene foams nucleated by 150SiO2-RP. SEM images show the number of cells in the occasion of multiple cell nucleating events occurring around a particle (PDF)

AUTHOR INFORMATION

Corresponding Authors

Joost Duvigneau− Materials Science and Technology of Polymers, MESA+ Institute for Nanotechnology, University of Twente 7500 AE Enschede, The Netherlands; orcid.org/0000-0002-2810-2768; Email:j.duvigneau@utwente.nl

G. Julius Vancso− Materials Science and Technology of Polymers, MESA+ Institute for Nanotechnology, University of Twente 7500 AE Enschede, The Netherlands; orcid.org/0000-0003-4718-0507; Email:g.j.vancso@utwente.nl

Authors

Shanqiu Liu− Materials Science and Technology of Polymers, MESA+ Institute for Nanotechnology, University of Twente 7500 AE Enschede, The Netherlands

Sida Yin− Materials Science and Technology of Polymers, MESA + Institute for Nanotechnology, University of Twente 7500 AE Enschede, The Netherlands

Complete contact information is available at:

https://pubs.acs.org/10.1021/acsnano.9b06837

Notes

The authors declare no competingfinancial interest.

ACKNOWLEDGMENTS

The authors would like to thank the MESA+ Institute for Nanotechnology of the University of Twente for financial support. S.L. acknowledges the China Scholarship Council for funding.

REFERENCES

(1) Notario, B.; Pinto, J.; Rodriguez-Perez, M. Nanoporous Polymeric Materials: ANew Class of Materials with Enhanced Properties. Prog. Mater. Sci. 2016, 78, 93−139.

(2) Forest, C.; Chaumont, P.; Cassagnau, P.; Swoboda, B.; Sonntag, P. Polymer Nano-Foams for Insulating Applications Prepared from CO2Foaming.Prog. Polym. Sci. 2015, 41, 122−145.

(3) Liu, S.; Duvigneau, J.; Vancso, G. J. Nanocellular Polymer Foams as Promising High Performance Thermal Insulation Materials. Eur. Polym. J. 2015, 65, 33−45.

(4) Costeux, S. CO2-Blown Nanocellular Foams. J. Appl. Polym. Sci.

2014, 131, 41293.

(5) Chen, L.; Rende, D.; Schadler, L. S.; Ozisik, R. Polymer Nanocomposite Foams. J. Mater. Chem. A 2013, 1, 3837−3850.

(6) Eaves, D.Handbook of Polymer Foams; Rapra Technology Ltd.: Shrewsbury, 2004; pp 1−6.

(7) Notario, B.; Pinto, J.; Solorzano, E.; De Saja, J. A.; Dumon, M.; Rodríguez-Pérez, M. A. Experimental Validation of the Knudsen Effect in Nanocellular Polymeric Foams. Polymer 2015, 56, 57−67.

(8) Pinto, J.; Notario, B.; Verdejo, R.; Dumon, M.; Costeux, S.; Rodriguez-Perez, M. A. Molecular Confinement of Solid and Gaseous Phases of Self-Standing Bulk Nanoporous Polymers Inducing Enhanced and Unexpected Physical Properties. Polymer 2017, 113, 27−33.

(9) Lee, S.-T. Polymeric Foams: Technology and Developments in Regulation, Process, and Products; CRC Press: Boca Raton, 2009; pp 20−25.

(10) Notario, B.; Pinto, J.; Rodríguez-Pérez, M. Towards a New Generation of Polymeric Foams: PMMA Nanocellular Foams with Enhanced Physical Properties. Polymer 2015, 63, 116−126.

(11) Li, L.; Shen, X.; Hong, S. W.; Hayward, R. C.; Russell, T. P. Fabrication of Co-Continuous Nanostructured and Porous Polymer Membranes: Spinodal Decomposition of Homopolymer and Random Copolymer Blends. Angew. Chem., Int. Ed. 2012, 51, 4089−4094.

(12) Zhang, X.; Chang, D.; Liu, J.; Luo, Y. Conducting Polymer Aerogels from Supercritical CO2 Drying PEDOT-PSS Hydrogels. J.

Mater. Chem. 2010, 20, 5080−5085.

(13) Hedrick, J. L.; Miller, R. D.; Hawker, C. J.; Carter, K. R.; Volksen, W.; Yoon, D. Y.; Trollsås, M. Templating Nanoporosity in Thin-Film Dielectric Insulators. Adv. Mater. 1998, 10, 1049−1053.

(14) Park, S. H.; Xia, Y. Macroporous Membranes with Highly Ordered and Three-Dimensionally Interconnected Spherical Pores. Adv. Mater. 1998, 10, 1045−1048.

(15) Du Fresne Von Hohenesche, C.; Schmidt, D.; Schadler, V. Nanoporous Melamine-Formaldehyde Gels by Microemulsion Templating. Chem. Mater. 2008, 20, 6124−6129.

(16) Bledzki, A. K.; Faruk, O. Effects of the Chemical Foaming Agents, Injection Parameters, and Melt-Flow Index on the Micro-structure and Mechanical Properties of Microcellular Injection-Molded Wood-Fiber/Polypropylene Composites. J. Appl. Polym. Sci. 2005, 97, 1090−1096.

(17) Klempner, D. Handbook of Polymeric Foams and Foam Technology; Hanser: Munich, 1991; pp 6−13.

(18) Zeng, C.; Han, X.; Lee, L. J.; Koelling, K. W.; Tomasko, D. L. Polymer-Clay Nanocomposite Foams Prepared Using Carbon Dioxide.Adv. Mater. 2003, 15, 1743−1747.

(19) Park, C. B.; Behravesh, A. H.; Venter, R. D. Low Density Microcellular Foam Processing in Extrusion Using CO2.Polym. Eng.

Sci. 1998, 38, 1812−1823.

(20) Tomasko, D. L.; Li, H.; Liu, D.; Han, X.; Wingert, M. J.; Lee, L. J.; Koelling, K. W. A Review of CO2Applications in the Processing of

Polymers. Ind. Eng. Chem. Res. 2003, 42, 6431−6456.

(21) Jacobs, L. J.; Kemmere, M. F.; Keurentjes, J. T. Sustainable Polymer Foaming Using High Pressure Carbon Dioxide: A Review on Fundamentals, Processes and Applications. Green Chem. 2008, 10, 731−738.

(22) Aram, E.; Mehdipour-Ataei, S. A Review on the Micro-and Nanoporous Polymeric Foams: Preparation and Properties. Int. J. Polym. Mater. 2016, 65, 358−375.

(23) Costeux, S.; Lantz, D. R.; Beaudoin, D. A.; Barger, M. A. Continuous Process for Extruding Nanoporous Foam. U.S. Patent 9145478B2, 2015.

(24) Sandler, J. K. W.; Francis, T.; Lopes, P. M. S. Nanoporous Polymer Foams. U.S. Patent 8529808B2, 2013.

(25) Costeux, S.; Zhu, L. Low Density Thermoplastic Nanofoams Nucleated by Nanoparticles.Polymer 2013, 54, 2785−2795.

(26) Costeux, S.; Bunker, S. P.; Jeon, H. K. Homogeneous Nanocellular Foams from Styrenic-Acrylic Polymer Blends. J. Mater. Res. 2013, 28, 2351−2365.

(27) Liao, Z.-E.; Yeh, S.-K.; Chu, C.-C.; Tseng, T.-W. Critical Parameters of Generating PMMA Nanocellular Foam.Annu. Technol. Conf.-Soc. Plast. Eng. 2016, 1773−1778.

(28) Tammaro, D.; Astarita, A.; Di Maio, E.; Iannace, S. Polystyrene Foaming at High Pressure Drop Rates. Ind. Eng. Chem. Res. 2016, 55, 5696−5701.

(29) Pinto, J.; Dumon, M.; Pedros, M.; Reglero, J.; Rodriguez-Perez, M. A. Nanocellular CO2 Foaming of PMMA Assisted by Block

Copolymer Nanostructuration. Chem. Eng. J. 2014, 243, 428−435. (30) Li, L.; Nemoto, T.; Sugiyama, K.; Yokoyama, H. CO2Foaming

in Thin Films of Block Copolymer Containing Fluorinated Blocks. Macromolecules 2006, 39, 4746−4755.

(31) Spitael, P.; Macosko, C. W.; McClurg, R. B. Block Copolymer Micelles for Nucleation of Microcellular Thermoplastic Foams. Macromolecules 2004, 37, 6874−6882.

(32) Yokoyama, H.; Sugiyama, K. Nanocellular Structures in Block Copolymers with CO2-Philic Blocks Using CO2as a Blowing Agent:

Crossover from Micro-to Nanocellular Structures with Depressuriza-tion Temperature. Macromolecules 2005, 38, 10516−10522.

(33) Liu, S.; Zoetebier, B.; Hulsman, L.; Zhang, Y.; Duvigneau, J.; Vancso, G. J. Nanocellular Polymer Foams Nucleated by Core-Shell Nanoparticles. Polymer 2016, 104, 22−30.

(34) Lee, L. J.; Zeng, C.; Cao, X.; Han, X.; Shen, J.; Xu, G. Polymer Nanocomposite Foams.Compos. Sci. Technol. 2005, 65, 2344−2363. (35) Ji, G.; Zhai, W.; Lin, D.; Ren, Q.; Zheng, W.; Jung, D. W. Microcellular Foaming of Poly(Lactic Acid)/Silica Nanocomposites in Compressed CO2: Critical Influence of Crystallite Size on Cell

Morphology and Foam Expansion. Ind. Eng. Chem. Res. 2013, 52, 6390−6398.

(36) Rende, D.; Schadler, L. S.; Ozisik, R. Controlling Foam Morphology of Poly(Methyl Methacrylate) via Surface Chemistry and Concentration of Silica Nanoparticles and Supercritical Carbon Dioxide Process Parameters. J. Chem. 2013, 2013, 1−13.

(37) Zhai, W.; Yu, J.; Wu, L.; Ma, W.; He, J. Heterogeneous Nucleation Uniformizing Cell Size Distribution in Microcellular Nanocomposites Foams. Polymer 2006, 47, 7580−7589.

(38) Yuan, H.; Xiong, Y.; Luo, G.; Shen, Q.; Zhang, L. The Influence of In Situ Synthesized Nanoparticles on Microstructure and Compression Properties of Polymer Foams during Supercritical Carbon Dioxide Foaming. J. Appl. Polym. Sci. 2017, 134, 44629.

(39) Liberman, A.; Mendez, N.; Trogler, W. C.; Kummel, A. C. Synthesis and Surface Functionalization of Silica Nanoparticles for Nanomedicine. Surf. Sci. Rep. 2014, 69, 132−158.

(40) Bagwe, R. P.; Hilliard, L. R.; Tan, W. Surface Modification of Silica Nanoparticles to Reduce Aggregation and Nonspecific Binding. Langmuir 2006, 22, 4357−4362.

(41) Yang, J.; Sang, Y.; Chen, F.; Fei, Z.; Zhong, M. Synthesis of Silica Particles Grafted with Poly(Ionic Liquid) and Their Nucleation Effect on Microcellular Foaming of Polystyrene Using Supercritical Carbon Dioxide. J. Supercrit. Fluids 2012, 62, 197−203.

(42) Siripurapu, S.; DeSimone, J. M.; Khan, S. A.; Spontak, R. J. Low-Temperature, Surface-Mediated Foaming of Polymer Films. Adv. Mater. 2004, 16, 989−994.

(43) Goren, K.; Chen, L.; Schadler, L. S.; Ozisik, R. Influence of Nanoparticle Surface Chemistry and Size on Supercritical Carbon Dioxide Processed Nanocomposite Foam Morphology. J. Supercrit. Fluids 2010, 51, 420−427.

(44) Miller, M. B.; Luebke, D. R.; Enick, R. M. CO2-Philic

Oligomers as Novel Solvents for CO2Absorption.Energy Fuels 2010,

24, 6214−6219.

(45) Wang, H.; Li, W. Selective Ultrasonic Foaming of Polymer for Biomedical Applications. J. Manuf. Sci. Eng. 2008, 130, 021004.

(46) Liu, Q.; Zhu, Y.; Yang, G.; Yang, Q. Nucleation Thermodynamics inside Micro/Nanocavity. J. Mater. Sci. Technol. 2008, 24, 183−186.

(47) Qian, M.; Ma, J. The Characteristics of Heterogeneous Nucleation on Concave Surfaces and Implications for Directed Nucleation or Surface Activity by Surface Nanopatterning. J. Cryst. Growth 2012, 355, 73−77.

(48) Maksimov, A. O.; Kaverin, A. M.; Baidakov, V. G. Heterogeneous Vapor Bubble Nucleation on a Rough Surface. Langmuir 2013, 29, 3924−3934.

(49) Du, X.; Liu, X.; Chen, H.; He, J. Facile Fabrication of Raspberry-Like Composite Nanoparticles and Their Application as Building Blocks for Constructing Superhydrophilic Coatings. J. Phys. Chem. C 2009, 113, 9063−9070.

(50) Qian, Z.; Zhang, Z.; Song, L.; Liu, H. A Novel Approach to Raspberry-Like Particles for Superhydrophobic Materials. J. Mater. Chem. 2009, 19, 1297−1304.

(51) Du, X.; He, J. A Self-Templated Etching Route to Surface-Rough Silica Nanoparticles for Superhydrophobic Coatings. ACS Appl. Mater. Interfaces 2011, 3, 1269−1276.

(52) Li, D.; Zhu, Y.; Mao, C. One-Pot Synthesis of Surface Roughness Controlled Hollow Silica Spheres with Enhanced Drug Loading and Release Profiles under Ambient Conditions in Aqueous Solutions. J. Mater. Chem. B 2013, 1, 5515−5520.

(53) Tsai, H.-J.; Lee, Y.-L. Facile Method to Fabricate Raspberry-Like Particulate Films for Superhydrophobic Surfaces. Langmuir 2007, 23, 12687−12692.

(54) Zakiyan, S. E.; Famili, M. H. N.; Ako, M. Controlling Foam Morphology of Polystyrene via Surface Chemistry, Size and Concentration of Nanosilica Particles. J. Mater. Sci. 2014, 49, 6225−6239.

(55) Zhang, T.; Ge, J.; Hu, Y.; Zhang, Q.; Aloni, S.; Yin, Y. Formation of Hollow Silica Colloids through a Spontaneous Dissolution-Regrowth Process. Angew. Chem. 2008, 120, 5890−5895. (56) Zhang, T.; Zhang, Q.; Ge, J.; Goebl, J.; Sun, M.; Yan, Y.; Liu, Y.-s.; Chang, C.; Guo, J.; Yin, Y. A Self-Templated Route to Hollow Silica Microspheres. J. Phys. Chem. C 2009, 113, 3168−3175.

(57) Musić, S.; Filipović-Vinceković, N.; Sekovanić, L. Precipitation of Amorphous SiO2Particles and Their Properties. Braz. J. Chem. Eng.

2011, 28, 89−94.

(58) Kim, H.; Kim, H.-G.; Kim, S.; Kim, S. S. PDMS-Silica Composite Membranes with Silane Coupling for Propylene Separation. J. Membr. Sci. 2009, 344, 211−218.

(59) Liu, S.; Eijkelenkamp, R.; Duvigneau, J.; Vancso, G. J. Silica-Assisted Nucleation of Polymer Foam Cells with Nanoscopic Dimensions: Impact of Particle Size, Line Tension, and Surface Functionality. ACS Appl. Mater. Interfaces 2017, 9, 37929−37940.

(60) Thommes, M. Physical Adsorption Characterization of Nanoporous Materials. Chem. Ing. Tech. 2010, 82, 1059−1073.

(61) Rouquerol, F. Adsorption by Powders and Porous Solids: Principles, Methodology and Applications; Academic Press: Kidlington, Oxford, 2014; pp 237−251.

(62) Thommes, M.; Cychosz, K. A. Physical Adsorption Character-ization of Nanoporous Materials: Progress and Challenges. Adsorption 2014, 20, 233−250.

(63) Liu, S.; Pandey, A.; Duvigneau, J.; Vancso, J.; Snoeijer, J. H. Size-Dependent Submerging of Nanoparticles in Polymer Melts: Effect of Line Tension. Macromolecules 2018, 51, 2411−2417.

(64) Ally, J.; Molla, S.; Mostowfi, F. Condensation in Nanoporous Packed Beds. Langmuir 2016, 32, 4494−4499.

(65) Ullah, R.; Atilhan, M.; Diab, A.; Deniz, E.; Aparicio, S.; Yavuz, C. T. Synthesis, Characterization and Evaluation of Porous Polybenzimidazole Materials for CO2Adsorption at High Pressures.

Adsorption 2016, 22, 247−260.

(66) Jones, W.; Isaac, P.; Phillips, D. The Adsorption of Carbon Dioxide and Nitrogen at High Pressures by Porous Plugs of Lampblack. Trans. Faraday Soc. 1959, 55, 1953−1958.

(67) Fujiki, J.; Yamada, H.; Yogo, K. Enhanced Adsorption of Carbon Dioxide on Surface-Modified Mesoporous Silica-Supported Tetraethylenepentamine: Role of Surface Chemical Structure. Micro-porous MesoMicro-porous Mater. 2015, 215, 76−83.

(68) Sanz-Pérez, E.; Arencibia, A.; Sanz, R.; Calleja, G. An Investigation of the Textural Properties of Mesostructured Silica-Based Adsorbents for Predicting CO2Adsorption Capacity.RSC Adv.

2015, 5, 103147−103154.

(69) Fujiki, J.; Yogo, K. The Increased CO2Adsorption Performance

of Chitosan-Derived Activated Carbons with Nitrogen-Doping. Chem. Commun. 2016, 52, 186−189.

(70) Kumar, V.; Suh, N. P. A Process for Making Microcellular Thermoplastic Parts. Polym. Eng. Sci. 1990, 30, 1323−1329.